Configurable Antenna and Method of Operating Such a Configurable Antenna

1. Antenna apparatus comprising: a directional antenna comprising a plurality of antenna array components; a plurality of RF chains connected to the plurality of antenna array components; a transceiver connected to the plurality of RF chains, wherein each RF chain comprises in sequence: a switching stage having switching circuitry selectively to connect an antenna array component; a phase shifting stage having phase shifting circuitry; and a summation stage having summation circuitry, wherein at least two of the RF chains connected to different antenna array components share phase shifting circuitry and at least two of the RF chains connected to different antenna array components share summation circuitry, and wherein the plurality of RF chains comprises a further summation stage having further summation circuitry, wherein the further summation stage is between the switching stage and the phase shifting stage, and the further summation stage is configured to combine output from two of the plurality of antenna array components to forward to the shared phase shifting circuitry.

2. The antenna apparatus as claimed in claim 1 , wherein the plurality of RF chains comprises a gain stage having gain circuitry, wherein at least two of the RF chains connected to different antenna array components share gain circuitry.

3. The antenna apparatus as claimed in claim 2 , wherein the gain circuitry of the gain stages is responsive to a gain control signal to select a fixed gain.

4. The antenna apparatus as claimed in claim 2 , wherein the gain circuitry of the gain stages is responsive to a gain control signal to select a variable gain.

5. The antenna apparatus as claimed in claim 1 , wherein the phase shifting circuitry of the phase shifting stages comprises a plurality of fixed length phase paths, and the phase circuitry comprises phase selection circuitry responsive to a phase selection signal to route the RF chain via one of the plurality of fixed length phase paths.

6. The antenna apparatus as claimed in claim 1 , wherein the directional antenna is a uniform linear antenna array.

7. The antenna apparatus as claimed in claim 1 , wherein the plurality of antenna array components comprises a plurality of antenna array elements arranged in columns to form the antenna array components.

8. The antenna apparatus as claimed in claim 7 , wherein the antenna array elements at one end of the columns of antenna array elements are connected to a first RF chain which is independent of a second RF chain connected to the antenna array elements at an opposite end of the columns of antenna array elements.

9. The antenna apparatus as claimed in claim 1 , further comprising a mounting portion configured to be fixed relative to a physical location of the antenna apparatus, wherein the directional antenna is configured to be rotatably positioned about an axis with respect to the mounting portion, and the plurality of RF chains is fixedly located with respect to the directional antenna.

10. The antenna apparatus as claimed in claim 9 , wherein the plurality of RF chains is located behind the plurality of antenna array components.

11. The antenna apparatus as claimed in claim 1 , further comprising: a rear directional antenna, wherein a rear RF chain of the plurality of RF chains is connected to the rear directional antenna and the rear RF chain is at least partially shared with a RF chain connected to an antenna array component of the plurality of antenna array components; and at least one RF chain comprises a further switching stage, wherein the further switching stage is configured to selectively connect only one of: the antenna array component and the rear directional antenna to the at least partially shared RF chain.

12. The antenna apparatus as claimed in claim 11 , wherein the rear directional antenna is fixedly mounted with respect to the directional antenna, wherein the rear directional antenna is oriented in a substantially opposite direction to the directional antenna, and wherein the plurality of RF chains are located between the directional antenna and the rear directional antenna.

13. The antenna apparatus as claimed in claim 11 , wherein the rear directional antenna is a rear uniform linear antenna array.

14. The antenna apparatus as claimed in claim 1 , further comprising: a uniform circular antenna array comprising a plurality of circular antenna array components, wherein a uniform circular antenna RF chain of the plurality of RF chains is connected to a uniform circular antenna array component and the uniform circular antenna RF chain is at least partially shared with a RF chain connected to an antenna array component of the plurality of antenna array components; and at least one RF chain comprises a further switching stage, wherein the further switching stage is configured to selectively connect only one of: the antenna array component and the uniform circular antenna array component to the at least partially shared RF chain.

15. The antenna apparatus as claimed in claim 14 , comprising control circuitry to time-multiplex operation of the uniform circular antenna array and the directional antenna.

16. The antenna apparatus as claimed in claim 1 , further comprising beam pattern control circuitry to control activation, gain and phase of the antenna or antennas of the antenna apparatus such that the antenna apparatus is operated in a selected mode with a selected beam pattern of a set of beam patterns, wherein the set of beam patterns provides a range of directionality and interference nulling.

17. The antenna apparatus as claimed in claim 16 , wherein the beam pattern control circuitry is responsive to an instruction received from a wireless network controller for a wireless network comprising more than one antenna apparatus to cause the antenna apparatus to be operated in the selected mode with the selected beam pattern.

18. The antenna apparatus as claimed in claim 16 , wherein the beam pattern control circuitry is responsive to a configuration determined in the antenna apparatus to cause the antenna apparatus to be operated in the selected mode with the selected beam pattern.

19. The antenna apparatus as claimed in claim 16 , wherein the selected mode and beam pattern are used to operate the antenna apparatus in a point-to-point mode in a wireless network.

20. The antenna apparatus as claimed in claim 16 , wherein the selected mode and beam pattern are used to operate the antenna apparatus in a point to multi-point mode in a wireless network.

21. A method of operating an antenna apparatus comprising the steps of: connecting a plurality of antenna array components via a plurality of RF chains to a transceiver, wherein at least two of the RF chains connected to different antenna array components share phase shifting circuitry and at least two of the RF chains connected to different antenna array components share summation circuitry; and in forward or reverse sequence in at least one RF chain: selectively connecting an antenna array component to a shared RF chain; phase shifting using a shared phase shifting stage of the shared RF chain; summing using a shared summation stage of the shared RF chain; and in the plurality of RF chains, further summing between the selectively connecting and the phase shifting, and the further summing combines output from two RF chains of the plurality of antenna array components to forward to the shared phase shifting stage.

22. Antenna apparatus comprising: means for directionally transmitting and receiving wireless signals comprising a plurality of antenna array components; means for providing a plurality of RF chains to connected the plurality of antenna array components to a transceiver; means for transceiving signals carried by the plurality of RF chains, wherein each RF chain comprises in sequence: means for selectively disconnecting an antenna array component; means for phase shifting; and means for summing, wherein at least two of the RF chains connected to different antenna array components share the means for phase shifting and at least two of the RF chains connected to different antenna array components share the means for summing, wherein: the means for providing a plurality of RF chains comprises a further 20 means for summation, wherein the further means for summation is between the means for selectively disconnecting and the means for phase shifting, and the further means for summation for combining output from two of the plurality of antenna array components to forward to the shared means for phase shifting.